Experimental Study of Multi-Mesh Gear Dynamics

Del Donno, Andrew Mark

09 January 2009

No description available.

Mechanical Engineering

Dynamics

gears

idler

analytical modeling

modal testing, vibrations

A THEORETICAL AND EXPERIMENTAL INVESTIGATION OF MODULATION SIDEBANDS OF PLANETARY GEAR SETS

Inalpolat, Murat

26 August 2009

No description available.

Mechanical Engineering

planetary gears

modulations

sidebands

vibrations

noise

An Experimental Study on the Influence of Misalignments on the Static Transmission Error of Hypoid Gear Pairs

Makam, Sandeep

25 October 2010

No description available.

Mechanical Engineering

Hypoid Gears

Static Transmission Error

Assembly Misalignments

Encoders

Characterization and Reduction of Friction in a Hybrid Transmission

DuBois, Mark D.

10 1900

<p>The aim of this study was to explore environmentally friendly solutions to reduce the friction present in automotive transmissions.</p> <p>A 2005 Ford Escape Hybrid transmission was used in this study to establish reasonable operating conditions for the gear surfaces.</p> <p>Background on gear operation and surface interaction was studied to understand the nature of the contact between the gear surfaces. Based on this, a mathematical model of gear interaction was developed and used to bracket the loading conditions of the gear tooth interface to be up to 1.5GPa of contact pressure with 2m/s relative sliding velocity. This information was used to aid in the identification of suitable surface engineering technologies and set the operating conditions for reciprocating tribometer based measurements.</p> <p>Additionally, tribological tests were performed on pin-on-disc samples which were treated with various surface treatments. The resulting wear surfaces were then studied using optical and Scanning Electron Microscopy (SEM) as well as Raman Spectroscopy. These techniques were used to better understand the mechanisms associated with wear and the role that the surface treatments played in reducing wear. Based on the testing performed, the best surface treatment for this application was a super finishing process. This process also met cost and environmental constraints. An in-house dynamometer was also developed to be used in the future full scale testing of a transmission.</p> / Master of Applied Science (MASc)

Friction

Coatings

Tribology

Surface Engineering

Transmission

Gears

Tribology

Tribology

Optimum Computer Design of External Spur Gears

Stratton, John

04 1900

<p> Using established spur gear design practice, a user-oriented computer-aided design package is created by which a user requires minimal knowledge of, or experience in either FORTRAN, optimization or gear design. although this practice is risky since the designer a judgement should be employed to the same extent as in a manual design. The package is essentially material independent with options to specify the design variables as constant, standard or variable. The great flexibility incorporated in the routine enables the designer a full range of design features from control to power gearing. The structure of the package enables implementation of new theory or new optimization criteria with relative ease. </p> / Thesis / Master of Engineering (MEngr)

Computer Design

External Spur

Gears

computer-aided design

An Experimental Investigation of the Effect of Spacing Errors on the Loaded Transmission Error of Spur Gear Pairs

Anichowski, Brian, Jr.

01 September 2017

No description available.

Mechanical Engineering

Engineering

Tribodynamics of Right Angled Geared System

C Gopalakrishnan, Srikumar

January 2018

No description available.

Mechanical Engineering

Elastohydrodynamic lubrication

Hypoid gears

Spiral bevel gears

Oil film stiffness

Damping due to lubricant

Tribodynamics

A Theoretical and Experimental Investigation on Bending Strength and Fatigue Life of Spiral Bevel and Hypoid Gears

Hotait, Mohammad Adel

17 March 2011

No description available.

Mechanical Engineering

Hypoid Gears

Spiral Bevel Gears

Tooth Bending Fatigue Failure

Gear Root Stresses

Gear Misalignments

Multiaxial Fatigue

Semi-Analytical Model to Study Vibrations of High-Speed, Rotating Axisymmetric Bodies Coupled to Other Rotating/ Stationary Structures

Vaidya, Kedar Sanjay

20 May 2021

The vibration of complex mechanical systems that include coupled rotating and stationary bodies motivates this work. A semi-analytical model is developed for high-speed, compliant, rotating bodies. Exploiting the axisymmetry of the rotating body, the developed semi-analytical model only discretizes the two-dimensional radial cross-section; Fourier series are used in the circumferential direction. The corresponding formulation for thin-walled, axisymmetric shells is given. Even though the body is axisymmetric, its deflection as well as external forces, constraints, and supports acting on the body are allowed to be asymmetric. These asymmetric elements can be stationary or rotating. The model includes Coriolis and centripetal effects. The prestress (or geometric) stiffness matrix that arises from external forces and constant centripetal acceleration has additional terms compared to the literature, and these terms can significantly change the natural frequencies. Discrete stiffness-damper elements, elastic foundations, and constraint equations are used to couple the rotating body to other rotating and stationary bodies. The model is developed in a stationary reference frame to avoid time-dependent coefficients in the equations of motion when coupled to stationary components. Surface constraints are developed using equivalent force relations between multiple points on the surface and a reference node. Discrete stiffness-dampers, asymmetric elastic foundation, and asymmetric constraints introduce non-axisymmetry in the system. The speed-dependent natural frequencies and complex-valued vibration modes, presence of multiple Fourier harmonics in each mode, changes to critical speeds, divergence and flutter instability phenomena, and eigenvalue veering are investigated for spinning systems with asymmetric features. The developed semi-analytical model is used for rotationally periodic systems, for example, planetary gears. Rotationally periodic systems consist of multiple vibrating, rotating central components and substructures. The model is developed in a reference frame rotating with the central component that supports the substructures. Structured modal properties of the cyclically symmetric systems and diametrically opposed systems are investigated. The modes of the spinning system are categorized into translational-tilting, rotational-axial, and substructure modes. Time-varying coupling elements act as parametric excitation in the system. Large strain energy in the coupling elements lead to large parametric instability regions. The analytical closed-form expression of the parametric instability bandwidth obtained using a perturbation method compares well with numerical results from Floquet theory. / Doctor of Philosophy / Complex mechanical systems, for example, mechanical transmission, consist of coupled rotating and stationary bodies. The vibrations of rotating bodies are transmitted to the other bodies through coupling elements. To reduce weight of the system, the rotating bodies are made thin-walled resulting in increased flexibility of the body. The existing lumped parameter/rigid body models do not account for the flexibility of these rotating bodies. Conventional three-dimensional finite element models lead to a large number of degrees of freedom in the system, increasing the computational cost. We aim to develop a computationally efficient model to analyze the dynamics and vibration of complex mechanical systems. Most rotating bodies can be approximated as axisymmetric. The axisymmetric property of the rotating body is harnessed to reduce the three-dimensional model of the body to a two-dimensional radial cross-section using Fourier series in the circumferential direction. This reduces the system degrees of freedom. Coriolis, centripetal, and prestress effects are included in the model. Discrete stiffness-dampers, elastic foundations, and constraint equations couple the rotating body to other rotating and stationary bodies. Non-axisymmetric coupling elements and forces introduce asymmetry in the system. The system model for these asymmetric systems are developed in a stationary reference frame to avoid time-dependent coefficient equations of motion. Flexible stationary bodies alter the natural frequencies and vibration modes of the system. Instabilities, critical speeds, effects of asymmetry on the natural frequencies and vibration modes of the system are investigated. The model is extended for rotationally periodic systems, for examples, planetary gears and bearings. This model is developed in the reference frame that rotates with the central component that supports substructures. Structured modal characteristics are observed for the rotationally periodic systems. Changing contact conditions act as a source of parametric excitation in systems. Parametric resonances occur when natural frequencies of vibration with large strain energy in the coupling elements sum to the excitation frequency. Parametric instability regions obtained using an analytical equation compare well with numerical results.

Rotating

axisymmetry

Finite element method

prestress

Fourier series

gears

high-speed

gyroscopic

surface relations

parametric resonance

planetary gears

An Experimental Investigation of Spin Power Losses of Planetary Gear Sets

Hilty, Devin R.

09 September 2010

No description available.

Automotive Materials

Energy

Engineering

Experiments

Mechanical Engineering

Transportation

planetary gears

efficiency

power loss

transmission efficiency

gears

gear design

planetary gear efficiency

planetary gear power loss